Abstract
The effectiveness of submerged synthetic aquatic vegetation on removal of colloids from flowing water was investigated to explore retention of particulate nonpoint source pollutants in aquatic systems. In colloid transport experiments, the deposition rate coefficient of colloids in dense vegetation is often taken as spatially constant. This assumption was tested by experiments and modeling aimed at quantifying changes in colloid retention with travel distance in submerged synthetic aquatic vegetation. Experiments were performed in a 10-m long, 0.6-m wide flume with a 5-cm water depth under different fluid velocities, initial colloid concentrations, and solution pH values. A model accounting for advection, dispersion and first-order kinetic deposition described the experimental data. The colloid deposition rate coefficient showed a power-law decrease with travel distance, and reached a steady state value before the end of the flume. Measured changes in colloid properties with transport distance (ζ potential and size) could not explain the observed decrease. While gravity was shown to contribute to the decrease, its impact was too weak to explain the decreasing power law trend, suggesting that processes operating in granular media to produce similar outcomes may also apply to submerged vegetation.
Highlights
ObjectivesThe objectives of this study are it is of practical significance to investigate the removal mechanism of colloids by as follows: (1) to determine whether the deposition rate coefficient of colloids in dense vegetation is constant; and (2) to explore if the mechanisms governing colloid deposition in dense vegetation correspond to those pertinent to porous media
This paper investigates the effectiveness of dense vegetation on removal of colloids, which are important nonpoint source pollutants
It showed that the colloid deposition rate decreased with travel distance, with the decline following a power law, and reached steady state after about 10 m
Summary
The objectives of this study are it is of practical significance to investigate the removal mechanism of colloids by as follows: (1) to determine whether the deposition rate coefficient of colloids in dense vegetation is constant; and (2) to explore if the mechanisms governing colloid deposition in dense vegetation correspond to those pertinent to porous media
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